Control circuits for high-frequency electronic converters



May 25, 1948. J. L. BOYER 2,442,258

CONTROL CIRCUITS FOR HIGH-FREQUENCY ELECTRONIC CONVERTERS Filed Dec. 14, 1946 2 Sheets$heet 1 I WNEE 13 iNVENTOR John L. Boyer.

ATTORNEY J. L. BOYER May 25, 1948.

CONTROL CIRCUITS FOR HIGH-FREQUENCY ELECTRONIC CONVERTERS Filed Dec. 14, 1946 2 Sheets-Sheet 2 R. my mw MB L, n M J WITNESSES:

ATTORN EY Patented May 25, 1948 CONTROL 'CIRCUITS FOR HIGH-FREQUENCY ELECTRONIC CONVERTERS John L. Boyer, Wilkinsburg, Pa., assignor to Westinghouse Electric Corporation. East Pittsburgh, Pa., a corporation 'of Pennsylvania Application' llecember 14, 1946, "Serial No..716,'1-96 13Claims. 1

My invention relates to electronic @frequencychangers or converters for converting directly from alternating current of 'one frequency to alternating :current of a higher frequency. uMore particularly,-'-my invention relates to high-frequency converters utilizing vgas or vapor-filled tubes-whereby an output can be obtained,-having a kilowatt rating which is greater than that which can be: economically obtained :with high-vacuum tubes.

An-important field of application ofthe invention is in supplying energy for an induction furnace requiring frequencies in the range ;of from 1000 to 2000 cyclesper second, more or-less.

This is a frequency-range in which rotating.

motor-generator sets have poor efficiency and poor regulating characteristics, and in 'which high-vacuum-tube voscillators can not be economically vused.

The principal object of mypresent invention isto providenew excitation control-circuits for high-.frequency converters of the type which I have mentioned, and more particularly for highfrequency converters utilizing ignitrons.

There have been two reasons why ignitrons have not-been utilized heretofore, as converters for changingieither a direct-current inputor a commercialfrequency alternating-current input, into frequencies as'high as 1000.cycles, more or less. One drawbackhaslbeen the vamount of power which is requiredto energize the 'ignitor, which runs into commercially prohibitive amounts fof excitation-power, with correspondinglyfdifficult control; when t'helignitor'must be energizechonce each half-cycle, at the high-frequency rate. A second, and perhaps more fundamental, drawback hasbeen that, regardless of poWer.requirements,.and regardless .of cost, the initiation of Lthe ignitor excitation requires a variable time of 'the'order of one millisecond, which is moreorless immateriahfor.Gil-cycle operation, but which amounts to about 360 electrical degrees for '1000-lcycle operation; an'dthis ignitor-exciting time isv a random phenomenon, subject to .wide.'fiuctuations' from cycle '.to cycle, with fluctuations so great as'to'make itimpracticablefhereto'fore, 'to "control the "ignitor at a frequency approaching anything like 1000 cycles.

It' is" an object of my present inve'ntionto provide an alternatingmurrent frequency-converter utilizing ignitronsfor converting directly froma commercial frequencyof 60 cycles or the like, to a highirequency of the'orderof 100-0 cycles or the like. The Vexcitation circuits consist 'of "three parts? (1-) "an -input+frequency firing-circuit for theignitors, (2) excitation-grids and control or shieldedgrids with a negative direct-current bias and an. outputefrequency control-voltageapplied to saidgrids, so as to vperiodically; block the initiation .of the firing-operation vof the ignitrons, at the output-.frequency rate, and .(3) an auxiliary anode or electrode, lwithva holding circuit .for maintaining a holding-arc on the auxiliary anode for input-frequency degrees, orforas long a part of the positiverinputfrequency half-cycle as it may be desirableto keep on re'firingeach tube at the high-frequency rate. Theseexcitation-circuits .are utilized with suitable output power-circuits for commutatingithe output-current, or assisting in ,commutating the outputcurrent, .at ,the-highfrequency rate, a desirable poWer-circuitior this purpose being the subjectmatter of my concurrently filed application Serial No. 716,197,

A further object of my invention'is to vprovide a broad-range phase-adjustment means, for ad justing thefiring-time of a rectifier vor inverter tube, and including a holding-circuit, energized from two inputephases; through rectifiers.

'It is a still furtherpbject of my'invention to provide a multi-ignitron converter utilizing an output-frequency-modulated shield-grid-means, in combinationwith an input-frequency-energized ignitor and an auxiliary-anode holding- .circuit.

With the foregoing and other objects in view, my invention consists in the circuits, systems, methods, combinations and parts, hereinafter described and claimed, and illustrate'd in the accompanying 'drawing,'wherein Figures 1 and 2 are simplified diagrammatic views illustrating the essential features of two-different formsof embodimentof my invention, omitting known features of switches, voltage-regulators, and other like'features which are ,notnecessary' to an understanding of the presentinvention.

In Figure l, I show the fundamental features of the p'oWer-circuits and the excitation-circuits of a preferred form of embodiment of 'my invention, utilizing six ignitron tubes, I through which aresupplied' from a three-phase input-circuit 1 which is ene'rgized'froma commercial-frequency power-transformer 8, having delta-connectedprimary windings 9, and zigzag secondary windings l0 havinga neutral point ll. The'primary windings 9 are energized -irom a threephase circuit l3, of'-60 cycles or other frequency. The secondary windings I0 energize the threephaseinput-circuitl oftheignitrons I to 6.

"The i'gnitrons are disposed intwogroups, I, 2

and 3, and 4, 5 and 6, respectively. Each phase of the input-circuit 1 is connected to the anodecircuits M of two ignitrons, one in each group. The three cathode-circuits l5 of the tubes l, 2 and 3, in the first group, are connected to a common cathode-bus l6; while the three cathode-circuits l5 of the tubes 4, 5 and 6, of the other group, are connected to another common cathode-bus H.

As more particularly described and claimed in my copending application, a high-frequency loadcircuit is connected to the two cathode-buses i5 and I1, by means of an output-transformer or reactor having a mid-tapped primary winding 2|, the midpoint 22 of which is connected to the neutral point H of the secondary winding is of the power-supply transformer 8, preferably through a direct-current reactor 23, which reduces the circulation of the high-frequency fundamental and harmonic currents in the supplytransformer 8, and also helps to reduce any pulsation in the high-frequency output-voltage wave.

The output-circuit 24 of the converter is shown as being energized from a secondary winding 25 of the output-transformer 26, and it is shown as being connected to an induction furnace 26 which is symbolically represented by an inductance 21 and a resistance 28.

In most cases, it will be necessary to utilize a commutating-capacitor 3H, for effecting the highfrequency commutation of the output-currents of the converter, or for at least assisting in the commutation of such currents. As shown in Fig. 1, the commutating-capacitor at is connected across the two cathode-buses l6 and ll, that is, across the primary terminals of the outputtransformer 20. A second capacitor 3!, for power-factor-correction purposes, is also commonly connected across the terminals Of the in duction-furnace load 26, that is, across the secondary terminals of the output-transformer 25.

It is possible, of course, to omit either one of the capacitors 30 or 3!, and to utilize the remaining capacitor to take over the functions of both, increasing the size of the remaining capacitor, for this purpose. It is usually more economical, however, to utilize the capacitor 3! to adjust the power factor of the load to near unity, and to utilize the capacitor solely for commutating purposes, for alternately chargingfirst in one direction and then the other, during successive half-cycles of the output-frequency, cutting off the output-current at the end of each output-frequency half-cycle, thus extinguishing, or commutating, the load-currents flowing through the main anode-cathode circuits of the several tubes I to 6, according to whichever tube is carrying current at the moment.

In accordance with my present invention, a special excitation-circuit is utilizedfor the converter-tubes I to 6.

Each tube, in addition to its anode-circuit l4 and cathode-circuit I 5, is provided with a control or shielded grid 33, in closely spaced relation with respect to the anode, an excitation grid 34 in closely spaced relation to the control grid, an ignitor 35, and an auxiliary anode or electrode 36. A tiny circle or dot 3'! has been placed within the diagrammatic representation of each tube, as a convention for indicating the presence of a gas or vapor, or other means for causing the ignitor or other control-electrode of the tube to become ineffective, in general, to stop the firing of the tube, once the firing has been initiated. The outer grid 34 acts as a deionizing surface for the inner control grid 33. The spacings between the inner grid and the anode, and between the two grids, should be as small as is mechanically possible, usually about one-quarter of an inch. The grids should be thin, with small holes therein, usually about one-eighth to onequarter of an inch in diameter. By these expedients, the grids are made more effective to control the tubes at a high-frequency rate.

The exciting currents for the several ignitors 35, of the tubes l to (i, are supplied by a set or" three single-phase firing-circuit excitation-transformers 40, and six ignitor-coupling insulatingtransformers 4 i.

In accordance with my present invention, the number of ignitor-misfires may be reduced, by connecting the ignltor co-upling transformers l in series in pairs, so as to fire the two ignitcrs which should fire at the same time. The series connection has the advantage that, when one of the two ignitors does not fire as soon as the other, a double voltage is impressed upon the hardfiring ignitor. The series ignitor-firing effect can be obtained in a number of different ways, as by means of a mid-tapped balancing coil 42 which is connected between each secondary winding of the excitation-transformer 4i) and the two coupling-transformers 4! which ener ize the two ignitors 35 which are to be excited by that winding of the excitation-transformer.

The primary windings of the excitation-transformers 45 are energized from an auxiliary threephase bus as, which is energized from the secondary windings of an auxiliary transformer is, the primary windings of which are conne ted to the main power-circuit l3.

The firing-points, in the input-frequency cycles, are advanced or retarded by means of variably saturable reactors 45, which are connected in series with each of the three secondary windings oi the excitation-transformers 48, the saturation of these reactors being controllable by means of a direct-current saturating-coil which is excited from a battery N through a controllable rheostat 58.

During each firing half-cycle, the voltage deliveredby the secondary winding of the excitation-transformer 40 is built up upon an energystoring capacitor 49, which is connected in shunt across the firing-excitation circuit. To obtain a valve-action, a fixed saturating reactor 50 is serially connected between the capacitor 49 and the two ignitor-coupling transformers M which are served from that circuit. At a predetermined point in the half-cycle, this saturating reactor 50 becomes saturated, thus suddenly losing its impedance, and permitting a heavy current-impulse to be discharged from the capacitor 59 into the ignitor-coupling transformers 41.

The secondary winding of each ignitor-coupling transformer 4| delivers only the positive peaks of its current to the ignitor 35 of the associated one of the main tubes I to 6, this action being accomplished by means of a serially connected rectifier 5|. A return-path for the flux-decay current of the coupling-transformer 4! is provided in a known manner by means of a rectifier 52 which is connected across the transformersecondary.

Since my converter is converting from a relatively low frequency to a relatively high frequency, each low-frequency conducting-period, of each tube, must be broken up into a plurality of conducting and non-conducting periods, at the highfrequency rate.

It is .a ,feature of present inventionsthat the ,grids 33-and 34, nfeach of the conyertertubes [to 6, are utilized :to alternately-block and release the firingnf the several. tubes, at the The two..-grids .3-3 and 5 is-shown, which is, .ormay be, of a conventional and well-understood type,-so.-that nodetaileddescription thereof is needed. The.-oscill ation-generator 55. has two output-windings. strands}, whichare utilized to .provide two output-frequency circuits of oppositepotentials, one .being positive whilethe other is negative.

The grid-control circuits also include negative biasing-batteries158 .and 59 respectively, one loiasingebattery 58 being .for one group of converter-tubes, l, 2 and v3,-. whi1e.,the other bias-- ing-battery 53 .is for. .theothergroup, 4, 5 and 16. Since -each of :the two groups of converter-tubes has its :own cathode-circuit M5 or l 'l, -.which ;is common to all of the tubes/of that,.sgroup, the grids 33.and' 3:4; of all of the :tuhesoieach group canv be energized .fromzthe same high-frequency source. T,hus,the grids of the :tubes 1, 2',and 3 are energized from the high-frequency outputwinding 55, in series with the negative biasingbattery 58; while the, grids :ofthe tubes A, .5 and B are energized :from the high-frequencyoutputwinding '51, in. series with the negative biasingbattery :55. In .an illustrative case, anegative bias of about .100 .voltsxhasbeen .found advisable,

4 for thebatteries. 58 and "59, in combination witha peak oscillator-.voltage-of about .200yolts, on each of :theoscillator output-windingsfafi and 51, althoughitis to besunderstoodathat lam not. limited to any-particular voltages.

Since the ignitor *35of each-of the converter tubes is energized only .once vduring each. inputirequency cycle, and since theperiod duringzwhich an energizing current flows in itheaignitorisronly a brief portion of the input-frequency' cycle,5it

will be obvious :thatthe lengthof .theportion'of the inputs-frequency cycle during :which :anyconverter-tube could be-fired, by the control-action of th grids, at the high' frequency' rate -would be limited :to the same brief portion 0f :the low.-

frequency cycleas :the duration :of the 'flowof:

holding-arc thereon :for 120 input-frequency. 'de-- grees, plus the input-frequency commutatingangle of the tubes, which may bean'o't-her =or degrees, 'more or less.

Thus, in'Fig. 1, the -auxiliaryelectrodes F of the six converter-tubes l to '6 are energized froma set of single-phase holding-circuititransformers fit. "The three primary. :windings of :the holding-circuit transformers are=energized from the auxiliary Ithr-ee phase input-frequencyebus 43.

Each of the three h'olding circuit rtransformers 50; has .a .plurality 10ft secondary wind.- nssj; .anda ihese: seconda y -w nd ngs are i ustrated-as.rbeing connected: in two zigezag )wind- I ing-eonnections Stand 65, having neutral points attend ,6;1 ,--whichare connected :to the respective cathode-buses l 6-.,and- ,l 1. ;'I'-h,e -s eve;ral,;phaseterminals gof gthezzig-zag windingM areptilized to energize thev auxiliary anodes- ;36 .of. the. converter-tubes l, 2 and-=.3,. through:separatecurrgrent limiting resistorsrfifii while the {several phaseterminals-ofmadame-w ding 6.5 arelutilizedto energize the auxiliary :anodes36 ofsthe converter.- tubes 4; Stand 6, :each ,through its ownresistorifill.

-o, 1;der .,to -.obtain anauxiliary-anode energizationaperiodi of 1 -inputf,-requency degrees, or. more, ier-each 10f the-converteretubes 1| to==.6, each :tube ;has,-itsauxiliaryeanode; .36 energiz ed, not,=Qnly,.-firomthe usual phase-circuit, or terminal, :of ,shesholdingecircuit -.transformer-,-6D, but

al-sowinsnarallel ther with, fr m the 'n l es ngenhase circui as-sh-own, for examplesatfie. The raus lia ii do enereizationwcircui s nelude grectifi'ers whichare connected, in each circuit; in seriesmith -;each.;of the =phase-ter-mi ;nals of th'eisecondar-y :windines "54:-.al1d";5 5,; 1 to, :avoid short-icircuiting ithe. parallel-connected windings, wvhile :at ithersame time delivering only the positiveimpulses.:ofxcurrent lfrom the ,respective windings.

Inrthe operationof ithe convertingapparatus which-isvshown:in rEig. 11, it may beinotedathat, although thexmain.;converter-;tubes O; :6 are of ,aiatype zin whichineither :the two 'g t dsw33rr 34. ;together;;nor :the ignitor.35;, rnor the-,auxiliary -;anode. 36, incapable, :in general, .of' interrup i the'xiiow of,a.i.=,main-,cir,cuit current ingany tube, once the tube-has beenzfired :by establishing an are between the; mainx'anode ;and the cathode, within the :tube, nevertheless a --;10ad. circuit=-is provided. "which:ris.. ofsuch character as to be able toaetfect: aperiodic interruption of the tubecurrent, 1 or .ofrthe :main ;arc--:;wi;thin the tube, .at the:output frequency':rate. In the circuitwhich is shown in Fig. ,lgsthis:currentsinterrupting or commute-ting function :is performedwprincipally by .;the' {parallel-connected capacitor 30.

in the controlecircuitsgit isto :be :noted that each-,ofr-thesmain converter-tubes I to- 6 sisafired once, during each :inpu-tefrequency "cycle, by the energization ofvits iignitorcircuit.' When the ignitorrSiznf any :tube establishes a firing-arc, the. auxiliary 5311 0616 r35 of'ithat tube practically instantlyrfiresaandapicksmp a holding-arc, .which is maintained ford-20 input-frequency ,degrees, plus. the ainputefreqnency commutatingetime of theatu'besnor LfOI" any other desired or necessary length: of. time. "ifIhe commutating-timeof the tubes isst-he time necessary to transfer .the main arc fromeione inputephase to another, -a-nd this :commutating'timewean be shortened Joy :utilizing a main atransformer 8which has :a; low reactance,

andzby otheremeans.

hile .vthe grids -.3 syandqsd can 1310b, in general, interrupt.:the main rare; in their tube, =once :said main, arc has :been establishedgthey --:can prevent, the-establishmentiof the :main :e :ifl-tha-grids are sufficiently enegatizve :xwit-h ;-res pect :to z the cathode :of the.:tube,, oriifrthezcontrol grid 33 has a potential which is more negative than a-cer- 'tainzacritieal zpotential. Z'It isrto the znotejdg-thatqthe grids=rz33 ands-314; of zeachzitube':a et oveln by combination ofea.anegativerhiasnand a singlephase ihigh-IfliBQIIBIlG-Y yoltaeamathafi. during .a portion of each:;highefrequencyegcycle;ztheq grids 1 are.:suificientlyxnegative: eto block .rthe gfiringr01 initiation of the main arc in the tube, after which the grids become sufiiciently positive, at a predetermined point in each high-frequency cycle, to permit the firing of the tube, provided that an exciting-arc is being carried, either by the ignitor 35 or by the auxiliary electrode 36, and provided, also, that the main anode of the tube is sufficiently positive with respect to the tube-cathode, at the moment.

It is to be noted that the grids of the tubes of one group of converter-tubes, namely the tubes I, 2 and 3, become sufiiciently positive, so as to release the respective tubes, for firing, during positive half-cycles of the output-frequency, while the grids of the tubes of the other group, 4, and 6, release their tubes during the negative half-cycles of the output-frequency. Thus, one or more tubes of one group is carrying current during one half-cycle of the outputfrequency, while none of the tubes of the other group are carrying current, the circuit being completed through the direct-current connection 22-23. The zig-zag connection of the maintransformer secondaries Ii] prevents this direct current from saturating the transformer.

During the next high-frequency half -cycle, the first group of tubes is non-conducting, while the second tube-group is conducting current.

During this interchange, when power is being supplied alternately by the cathode-bus l5 and by the cathode-bus ii, at the high-frequency rate, the parallel-connected capacitor 3[! is al ternately charging and discharging, first in one direction and then in the other, cooperating with the direct-current return-circuit path 22 -23 to also provide a return-path for whichever tube-group is carrying current at the moment, while also performing the function of interrupting the high-frequency current when the other tube-group is released, during any half-cycle of the high or output-frequency.

In Fig. 2, a different form of power-circuit is shown, by way of illustration, while the controlcircuits are essentially the same, with variations which are believed to be obvious, so that no further detailed explanation is considered necessary, in regard to the control-circuits of Fig. 2.

In Fig. 2, I show six main converter-tubes, TI to T5, which may be ignitrons similar to the tubes 5 to 6 of Fig. 1. These tubes are connected back-to-back, so as to be energized from a threephase supply-line L5, L2. L3, which is, in turn, energized from the three-phase star-connected secondary windings H, of a main power-transformer 72, having primary windings 13 which are energized from the Gil-cycle, or other relatively low-frequency. power-line 53. Thus, the anode circuit M of the tube Ti, and the cathode-circuit l5 cf the tube T4, are connected to the input line Ll; the anode-circuit M of the tube T2 and the cathode-circuit !5 of the tube T5 are connected to the input-line L2; and the anode-cir cuit M of the tube T3 and the cathode-circuit 15 of the tube T5 are connected to the input-line L3. The anode-circuits M of the tubes T4, T5 and T6 are connected to a common anode-bus '14; while the cathode-circuits l5 of the tubes Ti,

T2 and T3 are connected to a common cathodebus 15.

The two buses 14 and 75 are joined by a' midtapped commutating-reactor 75, having a midpoint H which is connected, through a high-frequency output-circuit T8, to the neutral point '19 of the power-transformer secondary I l.

The output circuit 18 serially includes a seriesconnected resonant-capacitor or commutatingcapacitor 8|, in series with the primary winding 82 of an output-transformer 83, which supplies an induction-furnace load 26, preferably having a powerfactor-correcting capacitor 3|, as described in connection with Fig. 1.

The fact that the main tubes TI to T6 are connected, in two groups, in back-to-back relation, makes it possible for the positive-connected tubes Tl, T2 and T3, or any one or more of them, to conduct the positive halves of the output-frequency current, while the negative-connected tubes, T4, T5 and T8, or any one or more of them, conduct the negative halves of the output-frequency current. In general, only one group of tubes conducts current at any time, first the positive, then the negative, then the positive, and so forth, the return-circuit, in either case, being back through the output-circuit 18 to the neutral point 19 of the supply-transformer. This return circuit '58 thus carries a single-phase alternating current, having the high frequency of the output-circuit. Because the output-frequency is considerably higher than the input-frequency, the input-transformer winding H would have a rather high reactance to the output-frequency current in the output-circuit I8, and hence the input-transformer windings H are shunted by three Y-connected capacitors 86, the neutral point of which is connected, at 81, to the neutral point '13 of the power-input transformer. The Y-connected capacitors 83 provide a low-impedance path for the high-frequency output-currents.

The serially-connected output-capacitor 8| cooperates with the inductance of the output-circuit l5lii to constitute an approximately resonant circuit, which is approximately resonant to the output-frequency, so that said capacitor Bl serves more or less as a commutating-capacitor. This commutating action varies, however, if the load or the power factor of the secondary outputcircuit 24 varies, but the mid-tapped commutating reactor it improves the stability of the converter by making it possible to release one group of tubes before the current has gone to zero in the other group of tubes.

The control circuits, in Fig. 2, are the same, in principle, as those which have already been shown and described in connection with Fig. l, the only essential difference being that, in Fig. 2, three of the tubes, T4, T5 and T6, do not have a common cathode-bus, as in Fig. 1, so that their control-circuits have to be separately connected to the several cathodes of said tubes, by suitably insulated transformers. Thus, for example, the high-frequency oscillator 55 has four separate output-windings, 90, 91, s2 and 93, instead or" the two output-windings 56 and 51 of Fig. 1. The oscillator output-windin 99 is connected to the cathode-bus 15 through the negative biasingbattery 53, as previously described; while the oscillator output-windings 9!, 92 and 53 are con nected, through separate biasing-batteries 94, and 95, to the respective supply-lines L, L2 and L3, which are connected to the cathode-terminals l5 of the respective tubes T4, T5 and T6. The oscillator output-windings 91, 92 and 93 separately energize the grids of these respective tubes T4, T5 and T5.

In Fig. 2, the auxiliary anodes 36 are energized from three ordinary holding-circuit transformers 69, without the parallel-phase energization which makes possible an unusually Wide range of phase-adjustment at 48 in Fig. 1.

of my present understanding, Iwi-sh it to beunderstood that I amnot limited to the circuits, or examples; or explanationhereingiven; I desire; therefore, that the appended claims-"shall be accorded the broadest construction consistent withthe'ir language.

I claim as my invention:'

1. combination, means forprovidin'g; an alternating-current input-circuit; means for providing an alternating current" output circuit, the output-circuit being at a irequency higher than the input-circuit; and a multi-tube' converter therebetween; eachtube of the'converte'r. having a main anode-cathodecircuit, a control ele'ctrode means, a, holding-'circuit'means, and "shield-grid means, said control-electrode" means and 'said shield-grid means being, in'generaL. incapable of interrupting the current inthemain anodecathode circuit of the tube, once. said tube has been fired; saidconverter comprising :a controlmeans' for each tube, including means for excitmg the control-electrode means a-t'the inputfrequency, means for exciting the holding-circuit means so as tothereafter maintain a ready-tofire condition in the tube for aconsiderable portion of an input-frequency cycle, and means for controlling the shield-grid means so as to alternately block and permit the firingof the tube on alternate half-cycles of the output-frequency; and said output-circuit including commutatingmeans for interrupting successive hali-cyclesloi the output-frequency current.

2'. In combination, means for providing an. alternating-current input-circuit; means for providing an alternating-current output-circuit, the output-circuit being at a frequency higher than the input-circuit; and a multi-ignitron converter therebetween, each ignitron of the converter having a main anode-cathode circuit, an ignitor, an auxiliary anode, and grid-means; said converter comprising a control-means for each ignitron, including means for exciting the ignitor at the input-frequency, means for exciting the auxiliary anode so as to thereafter maintain a holding-arc for a considerable portion of an input-frequency cycle, and means for controlling the grid-means so as to alternately block and permit the firing of the ignitron on alternate half-cycles of the output-frequency.

3. The invention as defined in claim 2, characterized by said output-circuit including commutating-means for interrupting successive halfcycles of the output-frequency current.

4. The invention as defined in claim 2, characterized by said input-circuit being polyphase, each input-frequency ignitor-exciting means including a broad-range phase-adjustment means for adlusting the time, in each input-phase, at which the ignitor is excited, and each auxiliary-anode exciting-means including holding-circuit transformer-secondaries of two difierent input-phases,

' with a serially connected rectifier associated with each, and parallel-circuit connections for exciting each auxiliary anode from said two transformersecondaries through their respective rectifiers.

5. In combination, means for providing a poly phase first circuit; means for providing a second circuit; and a multi-tube converter connected for interchanging power between said first and second circuits, each tube of the converter having a main anode-cathode circuit, a control-electrode circuit means including former-secondaries of two" d ifi'erent firste'circuit phases; with a seria-1ly-connected rectifier-"assoelated with each, and arallel-circuit connections for exciting eachholding circui-t means from' said two transformer-secondaries through their respective-rectifiers'.

6%" In -combination,means for providinga-poly phasefirst circuit;- means for providing a second circuit; and a multiigni-t'ron converter connected for interchanging power betweensaidfirstand second circuits, each 'ignitronof the converter having a main anode-cathode circuit, an ignit'or, and an'auxili-ary anode; said converter comprising a control-meansior'each ignitron, including a broad-range phase-adjustment means --fo'radjusting the time; 7 in each first-circuit phase; at whieh'theignitor is effectively-excited,'and means fol-"exciting the auxiliary anode -soas to thereafter maintain a holding-arc for a considerable portion of-aeycle of the first-circuit frequency, said auxiliary-anode -exciting--meansincluding homing-circuit transformer-secondaries of two different first-circuit" phases; with a serially connected: rectifier associated with each;- andrparallel-circuit connections for exciting "the auxiliary anode 'from" said two transformer-secondaries through their "respective rectifiers.

'7. In combination; means for providing a polyphase first circuit; means "forproviding an alternating-current second circuit having a .frequency diiferent i frorrr' the first circuit; :and a multi-ignitron converter connected forinterchanging power between said first and second circuits, each ignitron of the converter having a main anode-cathode circuit, an ignitor, a shieldgrid means, and an auxiliary anode; said converter comprising a control-means for each ignitron, including a holding-circuit associated with the auxiliary anode, a shield-grid voltage-source which is modulated at the frequency of one of said circuits, ignitor-energizing means, for energizing said ignitor at the first-circuit frequency, said ignitor-energizing means being phased suitably for determining the time, in each first-circuit cycle, at which the ignitor is effectively excited, and holding-circuit energizing-means for exciting the holding-circuit of the auxiliary anode so as to thereafter maintain a holding-arc for a considerable portion of a cycle of the firstcircuit frequency, said holding-circuit energizing-means including holding-circuit transformersecondaries of two different first-circuit phases, with a serially connected rectifier associated with each, and parallel-circuit connections for exciting the auxiliary anode from said two transformer-secondaries through their respective rectifiers.

8. In combination, means for providing a polyphase first circuit; means for providing an alternating-current second circuit having a frequency diiierent from the first circuit; and a multi-ignitron converter connected for interchanging power between said first and second circuits, each ignitron of the converter having a main anode-cathode circuit, an ignitor, a shieldl id ing-circuit; transgrid means, and an auxiliary anode; said converter comprising a control-means for each ignitron, including a holding-circuit associated with the auxiliary anode, a shield-grid voltage-source which is modulated at the frequency of the second circuit, ignitor-energizing means, for energizin said ignitor at the first-circuit frequency, said ignitor-energizing means being phased suitably for determining the time, in each first-circuit cycle, at which the ignitor is eifectively excited, and holding-circuit energizing-means, for exciting the holding-circuit of the auxiliary anode so as to thereafter maintain a holding-arc for a considerable portion of a cycle of the firstcircuit frequency, said holding-circuit energizingineans including holding-circuit transformersecondaries of two different first-circuit phases, with a serially connected rectifier associated with each, and parallel-circuit connections for exciting the auxiliary anode from said two transformer-secondaries through their respective rectifiers.

9. In combination, means for providing an alternating-current first circuit; means for providing an alternating-current second circuit having a frequency different from the first circuit; and a multi-ignitron converter connected for interchanging power between said first and second circuits, each ignitron of the converter having a main anode-cathode circuit, an ignitor, a shieldgrid means, and an auxiliary anode; said converter comprisin a, control-means for each ignitron, including a holding-circuit associated with the auxiliary anode, a shield-grid voltage-source which is modulated at the frequency of one of said circuits, and means for energizing the ignitor and the auxiliary-anode holding-circuit at the frequency of the first circuit.

10. The invention as defined in claim 9, in combination with phase-adjustment means for adjusting the time, in each first-circuit cycle, at which the ignitor is effectively excited.

11. In combination, means for providing an alternating-current first circuit; means for providing an alternating-current second circuit having a frequency different from the first circuit; and amulti-ignitron converter connected for interchanging power between said first and second circuits, each ignitron of the converter having a main anode-cathode circuit, an ignitor, a shieldgrid, means, and an auxiliary anode; said converter comprising a control-means for each ignitron, including a holding-circuit associated with the auxiliary anode, a shield-grid voltage-source which is modulated at the frequency of the second circuit, and means for energizing the ignitor and the auxiliary-anode holding-circuit at the frequency of the first circuit.

12. The invention as defined in claim 11, in combination with phase-adjustment means for adjusting the time, in each first-circuit cycle, at which the ignitor is effectively excited.

13. In combination, means for providing an alternating-current first circuit; means including a transformer having a single primary winding for providing an alternating-current second circuit having a frequency different from the first circuit; and a multi-ignitron converter connected for interchanging power between said first and second circuits, each ignitron of the converter having a main anode-cathode circuit, an ignitor, a shield-grid means, and an auxiliary anode; said converter comprising a controlmeans for each ignitron, including a holdingcircuit associated With the auxiliary anode, a shield-grid voltage-source which is modulated at the frequency of the second circuit, and means for energizing the ignitor and the auxiliaryanode holding-circuit at the frequency of the first circuit.

JOHN L. BOYER. 

